Dual-source vaporizer

ABSTRACT

A dual-source vaporizer that allows a user to produce dry herb vapor, e-liquid vapor, or a combination vapor having both dry herb vapor and e-liquid vapor. The dual-source vaporizer has a dry herb vaporizer, an e-liquid vaporizer, and a combining tank. The dual-source vaporizer has a microprocessor that directs the power flow from a rechargeable battery, and a selection slider that allows the user to select which vapor the dual-source vaporizer should produce. The dry herb vaporizer can be accessed through a removable plug located on the bottom of the dual-source vaporizer&#39;s main body, allowing for greater access and ease of cleaning.

FIELD OF THE INVENTION

The present device relates to a vaporizer that can provide vapor from multiple sources simultaneously within the same housing.

BACKGROUND

Portable vaporizers have become increasingly popular over the past few years as alternatives to traditional smoking methods. Vaporization allows for the delivery to the lungs of desired chemicals without the unhealthy by-products of the combustion process. Most vaporizers currently on the market are configured to vaporize a single substance, be it dried herbs, oils, or e-liquids. Each of the difference substances require subtle differences in the structures of the vaporization chamber to create the proper vaporization environment. Some vaporizers are modular, allowing for the user to switch out a vaporization chamber configured for one substance to a vaporization chamber configured for a different substance, and at least one vaporizer currently in production contains vaporizers for two different substances within the same housing, but requires the user to choose one or the other.

However, many users desire a mixture of two substances. For example, vaporizing dry herbs can leave an unpleasant taste in the mouth, which the vaporization of a flavored e-liquid could alleviate. What is needed is a dual-source vaporizer that is configured to allow a user to select from two separate vaporization sources or a combination thereof in order to satisfy the user's vaporization needs.

SUMMARY OF THE INVENTION

It is an aspect of the disclosure to provide a dual-source vaporizer that allows for the selection of multiple vaporization sources, either individually or in combination. These together with other aspects and advantages, which will be subsequently apparent, reside in the details of construction and operation as more fully hereinafter described and claimed, reference being had to the accompanying drawings forming a part hereof, wherein life numerals refer to like parts throughout.

A BRIEF DESCRIPTION OF THE DRAWINGS

Further features and advantages of the present device, as well as the structure and operation of various embodiments of the present device, will become apparent and more readily appreciated from the following description of the preferred embodiments, taken in conjunction with the accompanying drawings of which:

FIG. 1 is a perspective view of a dual-source vaporizer, according to an embodiment.

FIG. 2 is an exploded view of a dual-source vaporizer, according to an embodiment.

FIG. 3 is a cross section view of a dual-source vaporizer, according to an embodiment.

FIG. 4 is a cross section view of a dual-source vaporizer, according to an alternate embodiment.

FIG. 5 is an exploded view of a combination tank for a dual-source vaporizer, according to an embodiment.

FIG. 6 is an exploded view of a combination tank for a dual-source vaporizer, according to an alternate embodiment.

FIG. 7 is a bottom view of a dual-source vaporizer, according to an embodiment.

FIG. 8 is a block diagram illustrating a circuit for a dual-source vaporizer, according to an embodiment.

DETAILED DESCRIPTION

The present device can be a dual-source vaporizer that can allow a user to draw vapor from two vaporizing sources, either individually or in combination. In a preferred embodiment, one vaporizing source can be a dry herb vaporizer, while the second vaporizing source can be an e-liquid vaporizer. Alternately, a wax or oil vaporizer can be substituted for the dry herb vaporizer or the e-liquid vaporizer. The dry herb vaporizer can be contained within the main body of the dual-source vaporizer, while the e-liquid vaporizer can be contained in the combination tank of the dual-source vaporizer. The dual-source vaporizer can have a rechargeable battery, which can be used to power the dry herb vaporizer, the e-liquid vaporizer, and the dual-source vaporizer's circuit. The dual-source vaporizer's circuit can include a voltage controller for the e-liquid vaporizer, a temperature controller for the dry-herb vaporizer, a display screen configured to display voltage or temperature levels, a firing button, and a microprocessor. The microprocessor can be configured to regulate the voltage and temperature levels as defined by the user, as well as control the Display screen while the dual-source vaporizer is powered.

The dry herb vaporizer can comprise a series of nested elements. A dry herb chamber, into which the dry herb to be vaporized is placed, can be nested within a heating element. The heating element and dry herb chamber can be nested inside an insulator. The heating element, dry herb chamber, and insulator can be nested within a chamber casing. The entire dry herb vaporizer, comprising the dry herb chamber, heating element, insulator, and chamber casing can be nested within the main body of the dual-source vaporizer.

To use the dry herb vaporizer, the user can place a premeasured quantity of dry herbs into the dry herb chamber. The dry herb chamber can have a top collar having one or more exhaust holes, connected to a vapor funnel. The dry herb chamber can be made of a material that allows heat to spread evenly throughout the material, such as ceramic, metal, or any other material with similar properties. When the dry herb vaporizer is activated by the microprocessor, power can be applied to the heating element in order for the heating element to heat to the temperature set by the user. Once the heating element has reached the desired temperature, the user can inhale on the mouthpiece and begin drawing dry herb vapor. The dry herb vapor can travel out through the exhaust holes in the top collar into the vapor funnel, which can shunt the vapor into the combination tank via radial vapor holes on the combination tank connector located on the dual-vaporizer faceplate. For ease of cleaning, the dry herb chamber can be accessed from the bottom by removing a removable plug mounted on the underside of the main body. The user can replace the removable plug before more dry herb is placed into the dry herb chamber.

The e-liquid vaporizer can have an e-liquid chamber, having one or more air input ports, and an e-liquid element. The e-liquid chamber can be filled with e-liquid by the user. To use the e-liquid vaporizer, the user can depress the firing button, which can send a signal to the microprocessor to apply a voltage, set by the user using the voltage control, to the e-liquid element. The e-liquid element, upon application of the voltage, can heat to a temperature sufficient to produce the desired amount of e-liquid vapor for the user's inhalation. The air input ports, which can be regulated using the air flow slider, can allow a stream of ambient air into the e-liquid chamber, allowing the user to inhale the mixture of e-liquid vapor and ambient air.

In an embodiment, the combination tank can have an e-liquid stem, a dry herb stem, a combination chamber, and a mouthpiece stem. Additionally, the combination tank can have an e-liquid chamber, a selection slider, an air flow slider, and dry herb vapor input ports. The e-liquid stem and the dry herb stem can pass through the e-liquid chamber. The selection slider can lock in one of three positions: dry herb mode, e-liquid mode, or combination mode. In dry herb mode, the microprocessor can enable power distribution to the dry herb vaporizer and disable power distribution to the e-liquid vaporizer. As the user inhales, dry herb vapor can enter the combination tank through the dry herb vapor input ports, be drawn into the dry herb stem, pass through the dry herb stem into the combination chamber, and enter the user's mouth through the mouthpiece stem. In e-liquid mode, the microprocessor can enable power distribution to the e-liquid vaporizer and disable power distribution to the dry herb vaporizer. The e-liquid vapor, generated as described above, can enter the e-liquid stem, pass through the e-liquid stem into the combination chamber, and enter the user's mouth through the mouthpiece stem. In combination mode, the microprocessor can enable power distribution to both the dry herb vaporizer and the e-liquid vaporizer. Dry herb vapor and e-liquid vapor can be drawn into the dry herb stem and the e-liquid stem, respectively. Passing through their respective stems, the dry herb vapor and the e-liquid vapor can combine in the combination chamber, and the resulting combination vapor can enter the user's mouth through the mouthpiece stem.

In an alternate embodiment, the combination tank can have an e-liquid stem, a combination chamber, and a mouthpiece stem. Additionally, the combination tank can have an e-liquid chamber, a selection slider, an air flow slider, and dry herb vapor input ports. The e-liquid chamber can have an outer wall, and can be nested within the combination chamber. The e-liquid stem can pass through the e-liquid chamber. The selection slider can lock in one of three positions: dry herb mode, e-liquid mode, or combination mode. In dry herb mode, the microprocessor can enable power distribution to the dry herb vaporizer and disable power distribution to the e-liquid vaporizer. As the user inhales, dry herb vapor can enter the combination tank through the dry herb vapor input ports, be drawn directly into the combination chamber, and enter the user's mouth through the mouthpiece stem. In e-liquid mode, the microprocessor can enable power distribution to the e-liquid vaporizer and disable power distribution to the dry herb vaporizer. The e-liquid vapor, generated as described above, can enter the e-liquid stem, pass through the e-liquid stem into the combination chamber, and enter the user's mouth through the mouthpiece stem. In combination mode, the microprocessor can enable power distribution to both the dry herb vaporizer and the e-liquid vaporizer. Dry herb vapor and e-liquid vapor can be drawn into the combination chamber and the e-liquid stem, respectively. The dry herb vapor and the e-liquid vapor can combine in the combination chamber, and the resulting combination vapor can enter the user's mouth through the mouthpiece stem.

FIG. 1 is a perspective view of a dual-source vaporizer 100, according to an embodiment. The dual-source vaporizer 100 can have a main body 101 and a combination tank 102. The combination tank 102 can have a selection slider 107 and an airflow slider 108. The main body 101 can have a top plate 109, which can have dry herb vaporizer temperature controller 105 and an e-liquid voltage controller 106. The dry herb vaporizer temperature controller 105 and the e-liquid voltage controller 106 can each be buttons, a rotating wheel, a slider, or other mechanism that can allow the user to input a desired temperature or voltage, which can then transmit a signal to a microprocessor 210, which in turn can effectuate the setting the respective vaporizer. A display screen 104 can be used to display the temperature value or voltage value set by the temperature control 105 or voltage control 106. The dual-source vaporizer 100 can have a firing button 103, which, depending on the amount of presses, can be used to turn the vaporizer 100 on or off, or can be used to activate the e-liquid vaporizer.

FIG. 2 is an exploded view of a dual-source vaporizer 100, according to an embodiment. The dry herb vaporizer can be contained within the main body 101 of the dual-source vaporizer 100, while the e-liquid vaporizer can be contained in the combination tank 102 of the dual-source vaporizer 100. The dual-source vaporizer 100 can have a rechargeable battery 211, which can be used to power the dry herb vaporizer, the e-liquid vaporizer, and the dual-source vaporizer's circuit. The rechargeable battery can be configured to fit inside a battery sleeve 212 located on the bottom plate 110 of the main body 101, which can prevent unwanted movement of the battery 211 inside the main body 101. The dual-source vaporizer's circuit can include a voltage controller 106 for the e-liquid vaporizer, a temperature controller 105 for the dry-herb vaporizer, a display screen 104 configured to display voltage or temperature levels, a firing button 103, and a microprocessor 210. The microprocessor 210 can be configured to regulate the voltage and temperature levels as defined by the user, as well as control the display screen 104 while the dual-source vaporizer 100 is powered on.

The dry herb vaporizer can comprise a series of nested elements. A dry herb chamber 201, into which the dry herb (not shown) to be vaporized is placed, can be nested within a heating element 202. The heating element 202 and dry herb chamber 201 can be nested inside an insulator 203. The insulator 203 can be made from a material that does not conduct heat. The heating element 202, dry herb chamber 201, and insulator 203 can be nested within a chamber casing 204. The chamber casing 204 can be made of plastic, metal, or a combination thereof. The entire dry herb vaporizer, comprising the dry herb chamber 201, heating element 202, insulator 203, and chamber casing 204 can be nested within the main body 101 of the dual-source vaporizer 100.

To use the dry herb vaporizer, the user can place a premeasured quantity of dry herbs into the dry herb chamber 201. The dry herb chamber 201 can have a top collar 213 having one or more exhaust holes 214, connected to a vapor funnel 205. The dry herb chamber 201 can be made of a material that allows heat to spread evenly throughout the material, such as ceramic, metal, or any other material with similar properties. When the dry herb vaporizer is activated by the microprocessor 210, power can be applied from the battery 211 to the heating element 202 in order for the heating element 202 to heat to the temperature set by the user. Once the heating element 202 has reached the desired temperature, the user can inhale on the mouthpiece 250 and begin drawing dry herb vapor. The dry herb vapor (not shown) can travel out through the exhaust holes 214 in the top collar 213 into the vapor funnel 205, which can shunt the vapor into the combination tank 102 via radial vapor holes 113 on the combination tank connector 111 located on the dual-vaporizer face plate 109. For ease of cleaning, the dry herb chamber 201 can be accessed from the bottom of the dual-source vaporizer 100 by removing a removable plug 700 mounted on the bottom plate 110 of the main body 101. The user can replace the removable plug 700 before more dry herb is placed into the dry herb chamber 201.

FIG. 3 is a cross section view of a dual-source vaporizer 102, according to an embodiment. The combination tank 102 can have an e-liquid stem 302, a dry herb stem 301, a combination chamber 304, and a mouthpiece stem 305. Additionally, the combination tank 102 can have an e-liquid chamber 303, a selection slider (not shown), an air flow slider (not shown), and dry herb vapor input ports 310. The e-liquid stem 302 and the dry herb stem 301 can both pass through the e-liquid chamber 303. The selection slider (not shown) can lock in one of three positions: dry herb mode, e-liquid mode, or combination mode. In dry herb mode, the microprocessor 210 can enable power distribution to the dry herb vaporizer and disable power distribution to the e-liquid vaporizer. As the user inhales, dry herb vapor can enter the combination tank 102 through the dry herb vapor input ports 310 via the vapor funnel 205 and the radial vapor holes 113, be drawn into the dry herb stem 301, pass through the dry herb stem 301 into the combination chamber 304, and enter the user's mouth through the mouthpiece stem 305. In e-liquid mode, the microprocessor 210 can enable power distribution to the e-liquid vaporizer and disable power distribution to the dry herb vaporizer. The e-liquid vapor (not shown), generated as described below, can enter the e-liquid stem 302, pass through the e-liquid stem 302 into the combination chamber 304, and enter the user's mouth through the mouthpiece stem 305. In combination mode, the microprocessor can enable power distribution to both the dry herb vaporizer and the e-liquid vaporizer. Dry herb vapor and e-liquid vapor can be drawn into the dry herb stem 301 and the e-liquid stem 302, respectively. Passing through their respective stems, the dry herb vapor and the e-liquid vapor can combine in the combination chamber 304, and the resulting combination vapor can enter the user's mouth through the mouthpiece stem 305.

The e-liquid vaporizer can have an e-liquid chamber 303, having one or more air input ports 360, and an e-liquid element 306. The e-liquid chamber 303 can be filled with e-liquid (not shown) by the user. To use the e-liquid vaporizer, the user can depress the firing button 103, which can send a signal to the microprocessor 210 to apply a voltage, set by the user using the voltage controller (not shown), to the e-liquid element 306. The e-liquid element 306, upon application of the voltage, can heat to a temperature sufficient to produce the desired amount of e-liquid vapor for the user's inhalation. The air input ports 360, which can be regulated using the air flow slider (not shown), can allow a stream of ambient air into the e-liquid chamber 303, allowing the user to inhale the mixture of e-liquid vapor and ambient air. The combination tank 102 can be connected to the main body 101 via the combination tank screw 300 fitting into the combination tank connector 111.

FIG. 4 is a cross section view of a dual-source vaporizer, according to an alternate embodiment. The combination tank 102 can have an e-liquid stem 403, a combination chamber 402 having an outer wall 414, and a mouthpiece stem 406. Additionally, the combination tank 102 can have an e-liquid chamber 400 having an inner wall 401, a selection slider (not shown), an air flow slider (not shown), and dry herb vapor input ports 404. The outer wall 414 and the inner wall 401 can be substantially the same height. The e-liquid chamber 400 having an inner wall 401, and can be nested within the combination chamber 402 having an outer wall 414. The e-liquid stem 403 can pass through the e-liquid chamber 400. The selection slider (not shown) can lock in one of three positions: dry herb mode, e-liquid mode, or combination mode. In dry herb mode, the microprocessor 210 can enable power distribution to the dry herb vaporizer and disable power distribution to the e-liquid vaporizer. As the user inhales, dry herb vapor can enter the combination tank 102 through the dry herb vapor input ports 404 via the vapor funnel 205 and the radial vapor holes 113, be drawn directly into the combination chamber 402 in between the outer wall 414 and the inner wall 401, and enter the user's mouth through the mouthpiece stem 406. In e-liquid mode, the microprocessor 210 can enable power distribution to the e-liquid vaporizer and disable power distribution to the dry herb vaporizer. The e-liquid vapor, generated the same as in the primary embodiment, can enter the e-liquid stem 403, pass through the e-liquid stem 403 into the combination chamber 402, and enter the user's mouth through the mouthpiece stem 406. In combination mode, the microprocessor can enable power distribution to both the dry herb vaporizer and the e-liquid vaporizer. Dry herb vapor and e-liquid vapor can be drawn into the combination chamber 402 and the e-liquid stem 403, respectively. The dry herb vapor and the e-liquid vapor can combine in the combination chamber 402, and the resulting combination vapor can enter the user's mouth through the mouthpiece stem 406. The combination tank 102 can be connected to the main body 101 via the combination tank screw 405 fitting into the combination tank connector 111.

FIG. 5 is an exploded view of a combination tank for a dual-source vaporizer, according to an embodiment. The combination tank 102 can be configured to separate into an upper half 350 and a lower half 351. To fit together, the dry herb stem 301 can slide into the dry herb stem receiver 311, while the e-liquid stem 302 can fit into the e-liquid stem receiver 312. The combination tank can have a selector slider 107 and an airflow selector 108. The combination tank 102 can connect into the main body 101 by screwing the combination tank screw 300 into the screw hole 112 located in the center of the combination tank connector 111.

FIG. 6 is an exploded view of a combination tank for a dual-source vaporizer, according to an alternate embodiment. The combination tank 102 can be configured to separate into an upper half 450 and a lower half 451. To fit together, the e-liquid stem 403 can fit into the e-liquid stem receiver 313. The combination tank can have a selector slider 107 and an airflow selector 108. The combination tank 102 can connect into the main body 101 by screwing the combination tank screw 405 into the screw hole 112 located in the center of the combination tank connector 111.

FIG. 7 is a bottom view of a dual-source vaporizer, according to an embodiment. For ease of cleaning, the dry herb chamber 201 can be accessed from the bottom plate 110 of the main body 101 by removing a removable plug 700 mounted on the underside of the main body 100. The user can replace the removable plug 700 before more dry herb is placed into the dry herb chamber. The removable plug can be anchored to the main body 100 using a plug cord 702. The bottom plate 110 can also have a power connecter 701, which can be used to charge the battery (not shown).

FIG. 8 is a block diagram illustrating a circuit for a dual-source vaporizer, according to an embodiment. The dual-source vaporizer's circuit can include a voltage controller 106 for the e-liquid vaporizer, a temperature controller 105 for the dry-herb vaporizer, a display screen 104 configured to display voltage or temperature levels, and a microprocessor 210. The microprocessor 210 can be configured to regulate the voltage and temperature levels as defined by the user, as well as control the display screen 104 while the dual-source vaporizer is powered on. The dry herb vaporizer temperature controller 105 and the e-liquid voltage controller 106 can each be buttons, a rotating wheel, a slider, or other mechanism that can allow the user to input a desired temperature or voltage, which can then transmit a signal to a microprocessor 210, which in turn can effectuate the setting the respective vaporizer.

The selection slider 107 can lock in one of three positions: dry herb mode, e-liquid mode, or combination mode. In dry herb mode, the microprocessor 210 can enable power distribution to the dry herb vaporizer and disable power distribution to the e-liquid vaporizer. In e-liquid mode, the microprocessor 210 can enable power distribution to the e-liquid vaporizer and disable power distribution to the dry herb vaporizer. In combination mode, the microprocessor can enable power distribution to both the dry herb vaporizer and the e-liquid vaporizer.

When the dry herb vaporizer is activated by the microprocessor 210, to the heating element 202 in order for the heating element 202 to heat to the temperature set by the user by adjustment of the dry herb temperature controller 105. Once the heating element 202 has reached the desired temperature, which can be determined through the use of a thermometer 800, the user can inhale on the mouthpiece and begin drawing dry herb vapor. The microprocessor 210 can display the temperature measured by the thermometer 800 on the display screen 104.

To use the e-liquid vaporizer, the user can depress the firing button (not shown), which can send a signal to the microprocessor 210 to apply a voltage, set by the user using the voltage controller 106, to the e-liquid element 306. The e-liquid element 306, upon application of the voltage, can heat to a temperature sufficient to produce the desired amount of e-liquid vapor for the user's inhalation. The voltage level can be confirmed by a voltage meter 801 that is configured to measure the voltage being applied to the e-liquid element 306. The microprocessor 210 can display the voltage measured by the voltage meter 801 on the display screen 104.

A random access memory (RAM) module 802, connected to the microprocessor 210, can store all measured temperature and voltage values and set-points. A read-only memory (ROM) module 803, connected to the microprocessor 210, can store the dual-source vaporizer's basic input-output system (BIOS) and operating software (OS) needed for standard operations.

Although the present device has been described in terms of exemplary embodiments, none is limited thereto. Rather, the appended claims should be construed broadly to include other variants and embodiments of the present apparatus, which may be made by those skilled in the art without departing from the scope and range of equivalents of either the apparatus or the methods for using such an apparatus. 

What is claimed is:
 1. A dual-source vaporizer, comprising: a dry herb vaporizer, configured to upon activation produce a dry herb vapor which passes into a mouthpiece; an e-liquid vaporizer, configured to upon activation produce an e-liquid vapor which passes into the mouthpiece; a combining tank comprising the mouthpiece, a combination chamber, a dry herb stem, and an e-liquid stem; and a selection slider configured to be set among a dry herb mode, an e-liquid mode, and a combination mode; a circuit configured such that: when the selection slider is set to the dry herb mode, the dry herb vaporizer is activated and the e-liquid vaporizer is inactive; when the selection slider is set to the e-liquid mode, the e-liquid vaporizer is activated and the dry herb vaporizer is inactive; and when the selection slider is set to the combination mode, both the dry herb vaporizer and the e-liquid vaporizer are activated.
 2. The dual-source vaporizer as recited in claim 1, the dry herb vaporizer further comprising a temperature controller configured to adjust the temperature of the dry herb vaporizer.
 3. The dual-source vaporizer as recited in claim 1, the e-liquid vaporizer further comprising a voltage controller configured to adjust the voltage drawn by the e-liquid vaporizer.
 4. The dual-source vaporizer as recited in claim 1, the e-liquid vaporizer further comprising an air flow slider configured to regulate the amount of ambient air entering the e-liquid vaporizer.
 5. The dual-source vaporizer as recited in claim 1, wherein: the dry herb vaporizer further comprises a vapor funnel; the dual-source vaporizer further comprises a face plate comprising a combination tank connector having one or more radial vapor holes; and the combination tank further comprises one or more dry herb vapor input ports; wherein the dry herb vapor exits the dry herb vaporizer via the vapor funnel, passes through the radial vapor holes and into the combination tank through the dry herb vapor input ports.
 6. The dual-source vaporizer as recited in claim 5, wherein: the combination tank connector further comprises a screw hole; and the combination tank further comprises a combination tank screw; wherein the combination tank is attached to the combination tank connector by screwing the combination tank screw into the screw hole.
 7. The dual-source vaporizer as recited in claim 1, wherein: the dual-source vaporizer further comprises a bottom plate comprising a removable plug; and the dry herb vaporizer further comprises a dry herb chamber; wherein the dry herb chamber is accessed by removing the removable plug.
 8. The dual-source vaporizer as recited in claim 1, the combination tank further comprising an upper half, comprising an e-liquid stem receiver and a dry herb stem receiver, and a lower half; wherein the upper half and lower half are configured to fit together, the dry herb stem slides into the dry herb stem receiver and the e-liquid stem slides into the e-liquid stem receiver.
 9. A dual-source vaporizer, comprising: a dry herb vaporizer, configured to upon activation produce a dry herb vapor which passes into a mouthpiece; an e-liquid vaporizer, configured to upon activation produce an e-liquid vapor which passes into the mouthpiece; a combining tank comprising the mouthpiece, a combination chamber, and an e-liquid stem; and a selection slider configured to be set among a dry herb mode, an e-liquid mode, and a combination mode; a circuit configured such that: when the selection slider is set to the dry herb mode, the dry herb vaporizer is activated and the e-liquid vaporizer is inactive; when the selection slider is set to the e-liquid mode, the e-liquid vaporizer is activated and the dry herb vaporizer is inactive; and when the selection slider is set to the combination mode, both the dry herb vaporizer and the e-liquid vaporizer are activated.
 10. The dual-source vaporizer as recited in claim 9, wherein: the combination tank further comprises an outer wall; the e-liquid chamber further comprises an inner wall; the inner wall and the outer wall being substantially similar in height.
 11. The dual-source vaporizer in claim 9, the dual-source vaporizer further comprising no dry herb stem.
 12. The dual-source vaporizer as recited in claim 9, the dry herb vaporizer further comprising a temperature controller configured to adjust the temperature of the dry herb vaporizer.
 13. The dual-source vaporizer as recited in claim 9, the e-liquid vaporizer further comprising a voltage controller configured to adjust the voltage drawn by the e-liquid vaporizer.
 14. The dual-source vaporizer as recited in claim 9, the e-liquid vaporizer further comprising an air flow slider configured to regulate the amount of ambient air entering the e-liquid vaporizer.
 15. The dual-source vaporizer as recited in claim 9, wherein: the dry herb vaporizer further comprises a vapor funnel; the dual-source vaporizer further comprises a face plate comprising a combination tank connector having one or more radial vapor holes; and the combination tank further comprises one or more dry herb vapor input ports; wherein the dry herb vapor exits the dry herb vaporizer via the vapor funnel, passes through the radial vapor holes and into the combination tank through the dry herb vapor input ports.
 16. The dual-source vaporizer as recited in claim 15, wherein: the combination tank connector further comprises a screw hole; and the combination tank further comprises a combination tank screw; wherein the combination tank is attached to the combination tank connector by screwing the combination tank screw into the screw hole.
 17. The dual-source vaporizer as recited in claim 1, wherein: the dual-source vaporizer further comprises a bottom plate comprising a removable plug; and the dry herb vaporizer further comprises a dry herb chamber; wherein the dry herb chamber is accessed by removing the removable plug.
 18. The dual-source vaporizer as recited in claim 1, the combination tank further comprising an upper half, comprising an e-liquid stem receiver, and a lower half; wherein the upper half and lower half are configured to fit together and the e-liquid stem slides into the e-liquid stem receiver. 